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13.07.2019 | Original Research

Direct dip-coating of carbon nanotubes onto polydopamine-templated cotton fabrics for wearable applications

verfasst von: Md. Shak Sadi, Junjie Pan, Anchang Xu, Deshan Cheng, Guangming Cai, Xin Wang

Erschienen in: Cellulose | Ausgabe 12/2019

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Abstract

Simple and facile fabrication techniques to load conductive components onto textiles for wearable applications are highly demanded. In this work, highly conductive cotton fabrics were fabricated by dip-coating of single-walled carbon nanotubes (CNTs) after polydopamine (PDA) templating. The coated fabrics were characterized by scanning electron microscopy, X-ray photoelectron spectroscopy and energy dispersive X-ray spectrum. The introduction of PDA enhanced the adhesion between fiber surface and the loaded CNTs, resulting in a conductivity of 41.5 Ω/sq for the coated fabrics. The CNT-PDA-cotton fabric showed great durability against repeated mechanical deformation (bending, folding) or multiple washing cycles. The excellent strain sensing performance of the coated fabrics granted them the application potential in real-time monitoring of different human motions such as speaking, drinking, walking, bending of finger and knee etc. Furthermore, the composite fabrics showed outstanding electric heating performance with a rise in the surface temperature to about 120 °C within 20 s at 6 V. The fabrication of CNT-PDA-cotton composite fabrics provides a novel and simple way of developing textile-based wearable electronics and heaters.

Vorheriger Artikel Synthesis of P–N–Si synergistic flame retardant based on a cyclodiphosphazane derivative for use on cotton fabric

Nächster Artikel Correction to: Modification of hyperbranched hemicellulose polymer and its application in adsorbing acid dyes

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Amjadi M et al (2014) Highly stretchable and sensitive strain sensor based on silver nanowire–elastomer nanocomposite. ACS Nano 8(5):5154–5163CrossRefPubMed

Amjadi M et al (2016) Stretchable, skin-mountable, and wearable strain sensors and their potential applications: a review. Adv Func Mater 26(11):1678–1698CrossRef

Cai G et al (2017) Flexible and wearable strain sensing fabrics. Chem Eng J 325:396–403CrossRef

Cai G et al (2018) Large-scale production of highly stretchable CNT/cotton/spandex composite yarn for wearable applications. ACS Appl Mater Interfaces 10(38):32726–32735CrossRefPubMed

Chen L, Guo Z (2018) A facile method to mussel-inspired superhydrophobic thiol-textiles@ polydopamine for oil/water separation. Colloids Surf A 554:253–260CrossRef

Chen K et al (2017) Fabrication of core–shell Ag@ pDA@ HAp nanoparticles with the ability for controlled release of Ag⁺ and superior hemocompatibility. RSC Adv 7(47):29368–29377CrossRef

Cheng Y et al (2015) A stretchable and highly sensitive graphene-based fiber for sensing tensile strain, bending, and torsion. Adv Mater 27(45):7365–7371CrossRefPubMed

Di J et al (2016) Carbon-nanotube fibers for wearable devices and smart textiles. Adv Mater 28(47):10529–10538CrossRefPubMed

Du D et al (2016) Graphene coated nonwoven fabrics as wearable sensors. J Mater Chem C 4(15):3224–3230CrossRef

Hu Y et al (2018) A low-cost, printable, and stretchable strain sensor based on highly conductive elastic composites with tunable sensitivity for human motion monitoring. Nano Res 11(4):1938–1955CrossRef

Jia X et al (2014) Adhesive polydopamine coated avermectin microcapsules for prolonging foliar pesticide retention. ACS Appl Mater Interfaces 6(22):19552–19558CrossRefPubMed

Kang TJ et al (2010) Electromechanical properties of CNT-coated cotton yarn for electronic textile applications. Smart Mater Struct 20(1):015004CrossRef

Karim N et al (2017) Scalable production of graphene-based wearable e-textiles. ACS Nano 11(12):12266–12275CrossRefPubMedPubMedCentral

Li L et al (2017a) Surface micro-dissolution process for embedding carbon nanotubes on cotton fabric as a conductive textile. Cellulose 24(2):1121–1128CrossRef

Li Q et al (2017b) Reduced graphene oxide functionalized stretchable and multicolor electrothermal chromatic fibers. J Mater Chem C 5(44):11448–11453CrossRef

Li X et al (2018) Wearable strain sensing textile based on one-dimensional stretchable and weavable yarn sensors. Nano Res 11(11):5799–5811CrossRef

Li T et al (2019) Materials, structures, and functions for flexible and stretchable biomimetic sensors. Acc Chem Res 52(2):288–296CrossRefPubMed

Liu Y et al (2008) Functionalization of cotton with carbon nanotubes. J Mater Chem 18(29):3454–3460CrossRef

Liu Y et al (2015) One-step modification of fabrics with bioinspired polydopamine@ octadecylamine nanocapsules for robust and healable self-cleaning performance. Small 11(4):426–431CrossRefPubMed

MohanáKumar G (2015) Highly efficient CNT functionalized cotton fabrics for flexible/wearable heating applications. RSC Adv 5(14):10697–10702CrossRef

Molina J (2016) Graphene-based fabrics and their applications: a review. RSC Adv 6(72):68261–68291CrossRef

Qiao Y et al (2018) Multilayer graphene epidermal electronic skin. ACS Nano 12(9):8839–8846CrossRefPubMed

Ryu S et al (2015) Extremely elastic wearable carbon nanotube fiber strain sensor for monitoring of human motion. ACS Nano 9(6):5929–5936CrossRefPubMed

Samad YA et al (2017) From sewing thread to sensor: Nylon^® fiber strain and pressure sensors. Sens Actuators B Chem 240:1083–1090CrossRef

Seyedin S et al (2019) Textile strain sensors: a review of the fabrication technologies, performance evaluation and applications. Mater Horizons 6(2):219–249CrossRef

Shim BS et al (2008) Smart electronic yarns and wearable fabrics for human biomonitoring made by carbon nanotube coating with polyelectrolytes. Nano Lett 8(12):4151–4157CrossRefPubMed

Wang C et al (2016a) Carbonized silk fabric for ultrastretchable, highly sensitive, and wearable strain sensors. Adv Mater 28(31):6640–6648CrossRefPubMed

Wang Z et al (2016b) Polyurethane/cotton/carbon nanotubes core-spun yarn as high reliability stretchable strain sensor for human motion detection. ACS Appl Mater Interfaces 8(37):24837–24843CrossRefPubMed

Wang Y et al (2018) Ultra-stretchable, sensitive and durable strain sensors based on polydopamine encapsulated carbon nanotubes/elastic bands. J Mater Chem C 6(30):8160–8170CrossRef

Yan C et al (2014) Highly stretchable piezoresistive graphene–nanocellulose nanopaper for strain sensors. Adv Mater 26(13):2022–2027CrossRefPubMed

Yan D et al (2016) Polydopamine nanotubes: bio-inspired synthesis, formaldehyde sensing properties and thermodynamic investigation. J Mater Chem A 4(9):3487–3493CrossRef

Yang M et al (2018a) Conductive cotton fabrics for motion sensing and heating applications. Polymers 10(6):568CrossRefPubMedCentral

Yang Z et al (2018b) Graphene textile strain sensor with negative resistance variation for human motion detection. ACS Nano 12(9):9134–9141CrossRefPubMed

Yin B et al (2017) Highly stretchable, ultrasensitive, and wearable strain sensors based on facilely prepared reduced graphene oxide woven fabrics in an ethanol flame. ACS Appl Mater Interfaces 9(37):32054–32064CrossRefPubMed

Zeng W et al (2014) Fiber-based wearable electronics: a review of materials, fabrication, devices, and applications. Adv Mater 26(31):5310–5336CrossRefPubMed

Zeng L et al (2018) Macroscale porous carbonized polydopamine-modified cotton textile for application as electrode in microbial fuel cells. J Power Sources 376:33–40CrossRef

Titel: Direct dip-coating of carbon nanotubes onto polydopamine-templated cotton fabrics for wearable applications
verfasst von: Md. Shak Sadi
Junjie Pan
Anchang Xu
Deshan Cheng
Guangming Cai
Xin Wang
Publikationsdatum: 13.07.2019
Verlag: Springer Netherlands
Erschienen in: Cellulose / Ausgabe 12/2019
Print ISSN: 0969-0239
Elektronische ISSN: 1572-882X
DOI: https://doi.org/10.1007/s10570-019-02628-1

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